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Transition metal (Ni, co)‐doped graphitic carbon nitride/<scp>MoS<sub>2</sub></scp> heterojunctions as efficient photocatalysts for hydrogen evolution reaction under visible light

Gizem Yanalak, Seda Yılmaz, Zafer Eroğlu, Emre Aslan, Önder Metin, İmren Hatay Patır

2022International Journal of Energy Research25 citationsDOI

Abstract

Summary New photocatalysts comprising the 2D/2D heterojunction of graphitic carbon nitride (gCN) and molybdenum disulfide (MoS 2 ) semiconductors doped with nickel (Ni) or cobalt (Co), denoted as gCN/MoS 2 ‐M (M: Ni, Co), were fabricated for the photocatalytic hydrogen evolution reaction (HER) under visible light illumination. First, the binary gCN/MoS 2 heterojunctions were fabricated by using an in‐situ solvothermal method and then they were doped with Ni or Co via a chemical reduction method. The photocatalytic HER experiments revealed that the prepared gCN/MoS 2 ‐M (M: Ni, Co) photocatalysts showed enhanced HER activities and stabilities compared to pristine gCN and binary gCN/MoS 2 heterojunctions. Total H 2 productions of 5924 μmol g cat −1 and 5159 μmol g cat −1 in 8 hours were provided by using gCN/MoS 2 ‐Ni and gCN/MoS 2 ‐Co photocatalysts, respectively, under visible light illumination. The detailed structural characterization and examination of optical properties of gCN/MoS 2 ‐M (M: Ni, Co) photocatalysts revealed that their enhanced photocatalytic activities were attributed to the formation of ‘type‐I' 2D/2D heterojunction between gCN and MoS 2 semiconductors and the creation of S‐deficient MoS 2 nanostructures after Ni or Co doping, which promoted the separation of the photogenerated electron‐hole pairs, the charge mobility, and the visible light absorption.

Topics & Concepts

PhotocatalysisHeterojunctionMaterials scienceGraphitic carbon nitrideVisible spectrumMolybdenum disulfideCarbon nitrideDopingNitridePhotochemistryNanotechnologyChemistryCatalysisOptoelectronicsBiochemistryMetallurgyLayer (electronics)Advanced Photocatalysis Techniques2D Materials and ApplicationsMXene and MAX Phase Materials